JP5159675B2 - Alarm - Google Patents

Description

  The present invention relates to an alarm device using a battery as a power source.

  There is an alarm device (hereinafter referred to as a battery-type alarm device) that uses a battery as a power source in an alarm device that detects an alarm by detecting heat or smoke generated in a room or the like. Some battery-type alarm devices detect a battery voltage and, when the battery voltage is lower than a predetermined value, perform an alarm for prompting battery replacement or the like.

  As a process for monitoring the battery voltage of such a battery type alarm device, “a HIGH level signal is output to the base of the transistor 26 (switch ON), and a current is caused to flow through the resistor 24. A pseudo maximum load is generated, and at the same time, the output voltage of the battery 10 at this time (the output voltage is an analog value) is converted into a digital value via the A / D converter 200 configured in the control circuit 20. It is proposed that “take-in with” (for example, see Patent Document 1).

Japanese Patent Laying-Open No. 2008-65621 (page 6, FIG. 2)

  The conventional battery-type alarm device is said to be able to "read an accurate value of the battery voltage" in a state in which a current is caused to flow through a pseudo load and a maximum load is applied in a pseudo manner to the output side of the constant voltage circuit.

  However, loads such as a fire detection unit and an alarm sound output unit included in a battery-type alarm device may be supplied with current from a plurality of power supply systems. This is because when analog circuits and digital circuits are mixed or a circuit through which a large current flows is included, the power supply can be stabilized by dividing the supplied power supply system. Thereby, each circuit can perform a stable operation.

  For example, current is supplied through two paths: a path directly connected from a power source such as a battery to which a control circuit for determining battery voltage is connected, and a path connected via an internal power circuit such as a constant voltage circuit. Assume a load. In this case, even if a pseudo maximum load is generated on the output side of the constant voltage circuit as in Patent Document 1, the reference potential when the control circuit determines the battery voltage by the current directly supplied from the power supply. Therefore, the battery voltage cannot be accurately determined.

  Also, if the battery voltage is measured only on the primary side, the current consumption in the path through the constant voltage circuit will be ignored, and fluctuations that occur inherently cannot be taken into account, and an accurate battery voltage can be determined as well. I can't.

  Furthermore, even when a load such as a fire detection unit or an alarm sound output unit is supplied with power from one constant voltage circuit, the technique of Patent Document 1 can detect only the state of the battery voltage at the maximum load. Therefore, looking at the load of the entire battery-powered alarm device, it is small when only detecting a fire and large when sounding an alarm sound. The life is determined to be short, and the battery is wasted. It is desirable to be able to determine the battery life according to the amount of load, such as whether there is a remaining battery level at which "alarm sound can be sounded" or a remaining battery level at "only fire detection is possible".

  The present invention has been made in order to solve the above-described problems, and provides an alarm device capable of determining a battery voltage with high accuracy.

An alarm device according to the present invention includes a battery, a constant voltage circuit that keeps a voltage supplied from the battery constant, a state detection unit, and a state determination unit that determines a state based on an output signal of the state detection unit. A control unit that outputs an alarm based on a determination result of the state determination unit, a battery voltage detection unit that detects a voltage supplied from the battery to the control unit, the battery, and the constant A first operating unit connected to a voltage circuit and supplied with power from both, and connected to the battery in parallel with the first operating unit, and is normally in an OFF state, and is directly supplied with power from the battery. a first dummy load you corresponds to the maximum load of a circuit including a first operation unit is connected before and in parallel with the in Kijo voltage circuit first operation unit, the normal is a is OFF, from the constant voltage circuit A circuit including the first operation unit to which power is supplied Have a second dummy load you corresponds to the maximum load, the control unit measures the voltage value of the battery voltage detection unit in a state of electrically connected to the first dummy load and the second dummy load Thus, the battery life is determined .

In the alarm device, the first operation unit is an alarm sounding circuit.

Another alarm device according to the present invention determines a state based on a battery, a constant voltage circuit that keeps a voltage supplied from the battery constant, a state detector, and an output signal of the state detector. An alarm device comprising: a state determination unit; and a control unit that outputs an alarm based on a determination result of the state determination unit; a battery voltage detection unit that detects a voltage supplied from the battery to the control unit; is connected to the battery, and a second operation unit that will be powered from the battery, and connected to said constant-voltage circuit, the third operation unit that will be power supplied from the constant voltage circuit, the said battery second operation portion are connected in parallel, the normal is a OFF state, the third dummy load power directly you corresponds to the maximum load of a circuit including the second operation part to be supplied, before Kijo voltage circuit from the battery the third is connected in parallel with the operation unit, typically during the OFF-like A is said to have a fourth dummy load you corresponds to the maximum load of a circuit including the third operation unit power supply from the constant voltage circuit is supplied, the control unit, the third dummy load and the The battery voltage detector in each of a state in which the fourth pseudo load is electrically connected, a state in which the third pseudo load is electrically connected, and a state in which the fourth pseudo load is electrically connected The battery life is judged by measuring the voltage value .

In the other alarm device, the second operation unit is an alarm sounding circuit, and the third operation unit is a fire detection circuit or an indicator lamp circuit.

  According to the present invention, a pseudo load is provided for each power supply system supplied to the operating unit. Then, the battery voltage is measured in a state where all the pseudo loads are connected or in a state where any one of the pseudo loads is connected. For this reason, the battery life can be determined more accurately.

It is a block diagram which shows the structure of the fire alarm which concerns on Embodiment 1 of this invention. It is a block diagram of the alarm system comprised with the fire alarm which concerns on Embodiment 1 of this invention. It is a figure which shows the flow of the operation | movement of the periodical transmission which concerns on Embodiment 1 of this invention. It is a flowchart of the battery voltage determination operation | movement which concerns on Embodiment 1 of this invention. It is a block diagram which shows the structure of the fire alarm which concerns on Embodiment 2 of this invention. It is a block diagram which shows the structure of the fire alarm which concerns on Embodiment 3 of this invention. It is a flowchart of the battery voltage determination operation | movement which concerns on Embodiment 3 of this invention.

Embodiment 1 FIG.
Hereinafter, in the first embodiment, a case where the present invention is applied to a fire alarm device that is driven by a battery and performs wireless communication will be described as an example.

  FIG. 1 is a block diagram showing the main configuration of a fire alarm according to Embodiment 1 of the present invention. In FIG. 1, a fire alarm 10 includes a control circuit 1, a battery 2, a battery voltage detection circuit 4, a transmission / reception circuit 5, an antenna 6, a fire detection circuit 7, an alarm sounding circuit 8, an indicator light circuit 9, an internal power supply 12, The pseudo resistance circuits 21 and 22 are provided. In FIG. 1, a broken line represents a control signal between the control circuit 1 and each circuit.

The battery 2 supplies DC power to the transmission / reception circuit 5, the alarm sounding circuit 8, the internal power supply 12, and the like.
The internal power supply 12 is, for example, a constant voltage circuit that keeps the voltage supplied from the battery 2 constant. The internal power supply 12 supplies stable voltages to the control circuit 1, the alarm sounding circuit 8, the fire detection circuit 7, and the indicator lamp circuit 9, respectively.

  The battery voltage detection circuit 4 detects the voltage of the battery 2 applied to the internal power supply 12 and outputs a battery voltage detection signal corresponding to the detected voltage to the control circuit 1.

  The fire detection circuit 7 corresponds to a state detection unit of the present invention, detects a physical quantity or a physical change of a detection target such as smoke or heat based on a fire phenomenon, and outputs a signal corresponding to the detection content to the control circuit 1 To do.

  The alarm sounding circuit 8 is a circuit that controls the sounding operation by a buzzer / speaker or the like, and corresponds to a first operation unit of the present invention. The alarm sounding circuit 8 is connected to the battery 2 and is also connected to the internal power supply 12, and power is supplied from both the battery 2 and the internal power supply 12. The alarm sounding circuit 8 is subjected to the maximum load when sounding the alarm sound. Therefore, when the alarm sound is sounded, power is supplied from both the battery 2 and the internal power supply 12 and the alarm sound is not sounded (during standby). Is supplied with power from the internal power supply 12. Thereafter, the power supply from the internal power supply 12 is also cut off under the control of the control circuit 1, and the alarm sounding circuit 8 shifts to the low power consumption mode.

  The indicator lamp circuit 9 is a circuit that controls the lighting operation of indicator lamps such as light emitting diodes.

  The transmission / reception circuit 5 is connected to an antenna 6 for transmitting / receiving a radio signal. The transmission / reception circuit 5 performs a reception sampling operation at a predetermined cycle to process a radio signal input from the antenna 6, and performs a reception process in the case of a signal addressed to itself. In the case of other signals, reception processing is not performed. The received signal is output to the control circuit 1. The transmission / reception circuit 5 is controlled by the control circuit 1 to output an alarm signal to another fire alarm device when a fire is detected, and to transmit a status signal during regular transmission (the operation will be described later).

  The control circuit 1 has a function as a state determination unit that determines a fire state and the like based on a signal output from the fire detection circuit 7. Further, when it is determined that the state is a fire state, the alarm sounding circuit 8 and the indicator lamp circuit 9 are controlled to issue an alarm by sound and an indicator lamp. Moreover, while performing a required process based on the signal which the transmission / reception circuit 5 received, the transmission / reception circuit 5 is controlled as needed and signals, such as a status signal, are transmitted to another fire alarm device. The control circuit 1 corresponds to a state determination unit and a control unit of the present invention.

  Further, the control circuit 1 acquires the battery voltage signal detected by the battery voltage detection circuit 4 and compares the measured value of the battery voltage with a predetermined threshold value to determine the battery life.

  The storage element 11 is a nonvolatile memory such as an EEPROM, and stores programs executed by the control circuit 1 and various data.

  The pseudo resistance circuit 21 is a circuit composed of a resistor or the like for artificially applying a load to the primary side (input side) of the internal power supply 12, and is connected to the battery 2 in parallel with the alarm sounding circuit 8. Yes. The pseudo resistance circuit 21 has a resistance value that corresponds to the maximum load of the transmission / reception circuit 5 and the alarm sounding circuit 8 that are directly supplied with power from the battery 2.

  The pseudo resistance circuit 22 is a circuit configured by a resistor or the like for applying a pseudo load to the secondary side (output side) of the internal power supply 12, and the internal power supply 12 in parallel with the alarm sounding circuit 8. It is connected to the. The pseudo resistance circuit 22 has a resistance value corresponding to the maximum load of the control circuit 1, the alarm sounding circuit 8, the fire detection circuit 7, and the indicator lamp circuit 9 to which power is supplied from the internal power supply 12.

  The pseudo resistance circuits 21 and 22 are in an OFF state and are not electrically connected except when the battery voltage is detected.

  FIG. 2 is a diagram showing an alarm system 100 configured by a plurality of fire alarms 10 configured as described above. In FIG. 2, the alarm system 100 includes fire alarms 10a to 10d, and those that function as a master unit are referred to as a master unit 10a, and those that function as a slave unit are referred to as a slave unit 10b to a slave unit 10d. Solid lines connecting the fire alarm devices 10a to 10d indicate that wireless transmission / reception is possible.

In the alarm system 100 configured as described above, an operation when a fire occurs will be described.
When a fire occurs in the environment in which the main unit 10a is installed, the fire is detected by the fire detection circuit 7, the alarm sounding circuit 8 or the indicator light circuit 9 is used to give an alarm using sound or an indicator light, and an alarm about the fire Information is transmitted as an interlocking signal to the other slave units 10b to 10d. And the subunit | mobile_unit 10b-subunit | mobile_unit 10d which received the interlocking | linkage signal transmitted by the main | base station 10a performs a required alarm with an audio | voice and an indicator lamp. Thereafter, when the base unit 10a no longer detects a fire, the base unit 10a self-recovers and stops the alarm, and stops transmission of the interlock signal to the slave units 10b to 10d. And the subunit | mobile_unit 10b-the subunit | mobile_unit 10d which stopped receiving an interlocking signal also stops an alarm.

In addition, when a fire occurs in the environment where the child device 10b is installed, the child device 10b detects the fire by the fire detection circuit 7, performs an alarm by sound or an indicator lamp, and uses the information related to the fire as the interlocking signal. To the slave unit 10c and the slave unit 10d. Then, the master unit 10a, the slave unit 10c, and the slave unit 10d that have received the interlocking signal transmitted by the slave unit 10b perform a necessary alarm by voice or an indicator lamp.
Furthermore, the master unit 10a that has received the interlock signal generated by the slave unit 10b transfers the interlock signal to the slave units 10c and 10d other than the slave unit 10b that is the transmission source. Therefore, since the slave units are separated from each other, even if the interlock signal transmitted by the slave unit 10b is not received by the slave unit 10c and slave unit 10d, the interlock signal transferred by the master unit 10a is not the slave unit 10c. Is received by the machine 10d. Thereafter, when the slave unit 10b no longer detects a fire, the slave unit 10b self-recovers and stops the alarm, and stops transmission of the interlock signal to the master unit 10a, the slave unit 10c, and the slave unit 10d. The parent device 10a, the child device 10c, and the child device 10d that have not received the interlocking signal also stop the alarm.

  In addition, when any alarm device detects a fire and performs an interlocking alarm, if the alarm stop button of the interlocking fire alarm device 10 is pressed, the fire alarm devices 10 other than the fire source fire. Stop the alarm (linked alarm). When the alarm stop button of the fire source fire alarm 10 is pressed, the interlock alarm of the fire alarm device 10 to be interlocked is stopped, and only the sounding of the fire source fire alarm 10 is stopped (indicator light). Remains on). Furthermore, when a fire is detected again after the fire alarm 10 has recovered itself, the same operation as the first fire detection is performed. On the other hand, when a fire is not detected again, the routine shifts to a periodic transmission operation.

  As described above, when a fire occurs, the base unit 10a in the alarm system 100 and the slave units 10b to 10d perform a fire alarm in conjunction with each other, so that the fire can be more reliably warned.

Next, the periodic transmission operation during fire monitoring (steady state) of the parent device 10a and the child devices 10b to 10d constituting the alarm system 100 will be described.
Periodic transmission, for example, is to send each other a signal containing its own status information such as the remaining battery level and communication status to other fire alarms and to check the status of the other fire alarms to each other It is done as. The regular transmission is performed at a predetermined cycle (for example, once every 15 to 20 hours).

FIG. 3 is a diagram showing a flow of the regular transmission operation.
(S101)
When the base unit 10a reaches a predetermined transmission timing, the base unit 10a or a group to which the base unit 10a belongs, and information including a self-address and a group ID for identifying the transmission source are used as a state signal. It transmits to the subunit | mobile_unit 10d.

(S102, S103, S104)
Further, the slave units 10b to 10d receive the status signal from the master unit 10a and then, for example, identify the status information related to the device status such as the remaining battery level and the transmission source at the respective transmission timings. The information including the self address and group ID is transmitted to the parent device 10a as a status signal.
At this time, the master unit 10a and the slave units 10b to 10d can distinguish which fire alarm signal is from the self-address included in each status signal.

(S105)
When receiving the status signal transmitted from the slave unit 10b to the slave unit 10d, the master unit 10a returns a response signal to all the slave units.

Examples of the status information of the master unit 10a or the group to which it belongs include the sensor status (deterioration, contamination, etc.) of the fire detection circuit 7, the address or group ID of the slave unit in which an abnormality has occurred, and wireless communication. The address and group ID information of the slave unit that does not exist are listed. On the other hand, examples of the status information of the slave units transmitted from the slave units 10b to 10d to the master unit 10a include the sensor status (deterioration, contamination, etc.) of the fire detection circuit 7, the number of reception processes (the number of processes for radio other than the prescribed number). ) And the like.
When any fire alarm detects a fire, the operation proceeds to the above-described fire alarm operation.
In this way, the periodical transmission operation for confirming the state by transmitting various state information such as the battery remaining amount is performed every predetermined time, and the state of each fire alarm is confirmed.

  Next, the operation of determining the battery life by determining the battery voltage of the battery 2 in the fire alarm 10 configured as described above will be described. Here, it is assumed that the maximum electric load is applied to the fire alarm 10 when the alarm sounding circuit 8 sounds an alarm sound.

FIG. 4 is a flowchart showing a battery voltage determination operation in the first embodiment.
In FIG. 4, when the battery voltage detection timing comes (S201), the control circuit 1 turns on the pseudo resistance circuits 21 and 22 (S202). The battery voltage detection circuit 4 A / D converts the detected battery voltage and outputs this value (referred to as a battery voltage value) to the control circuit 1 (S203). The battery voltage value detected here is the measurement of the battery voltage of the battery 2 when a load equivalent to the maximum load of the transmission / reception circuit 5, the alarm sounding circuit 8, the fire detection circuit 7, and the indicator lamp circuit 9 is applied. Value.

The control circuit 1 compares the acquired battery voltage value with a predetermined threshold value for the battery exhaust voltage (S204), and determines that the battery voltage value is normal if the battery voltage value is equal to or greater than the threshold value (S205). Normal means that the battery is not dead.
On the other hand, if the battery voltage value is less than the threshold value, it is determined that the battery has run out (S206). In this case, for example, the alarm sounding circuit 8 and the indicator lamp circuit 9 are operated to notify the user that the battery is dead. Alternatively, a signal indicating that the battery is dead may be transmitted to another fire alarm or a monitoring device by the transmission / reception circuit 5. The voltage threshold is appropriately set in consideration of the value of the battery voltage necessary for the transmission / reception circuit 5 and the alarm sounding circuit 8 to operate at the maximum load.

  The above operation is repeated at predetermined intervals to periodically monitor the battery voltage state.

Next, the battery voltage value determined by the control circuit 1 will be described in detail.
First, since the control circuit 1 that determines the battery voltage is supplied with power from the internal power supply 12, the reference potential when the control circuit 1 determines the battery voltage is the output voltage of the internal power supply 12.

  When the alarm sounding circuit 8 is driven, the alarm sounding circuit 8 is supplied with power from both the battery 2 and the internal power supply 12. When power is supplied from the battery 2 to the alarm sounding circuit 8, the voltage supplied from the internal power supply 12 becomes smaller than when no power is supplied from the battery 2 to the alarm sounding circuit 8. This voltage drop increases as the difference between the voltage of the battery 2 and the output voltage of the internal power supply 12 decreases.

  Therefore, for example, when only the pseudo resistance circuit 22 is placed and a load is applied, if the battery voltage is detected in this state, the load current of the internal power supply 12 is more than that when the alarm sounding circuit 8 is actually driven. Get smaller. For this reason, the battery voltage recognized by the control circuit 1 becomes higher than when the alarm sounding circuit 8 actually sounds the alarm sound, and an error occurs.

  However, in the fire alarm device 10 according to the first embodiment, the pseudo resistance circuits 21 and 22 are arranged for each power supply system, and the battery voltage is determined in a state where both are turned on. For this reason, it is possible to perform more accurate battery voltage determination without causing the above-described error.

As described above, according to the fire alarm device 10 according to the first embodiment, in the electric circuit having a plurality of power supply systems, the pseudo resistance circuits 21 and 22 having the same resistance value as the maximum load of each power supply system are arranged. did. For this reason, the battery voltage can be detected in a state in which a current consumed in each power supply system is generated in a pseudo manner when the fire alarm 10 is at the maximum load. Therefore, the battery voltage can be determined more accurately.
Since the battery voltage can be accurately determined, the battery life can be determined more accurately. Since the fire alarm device needs to reliably perform the fire detection and the alarm when a fire is detected, which is its original function, it is necessary to accurately determine the battery life. This is because if the battery is left out, it cannot function. On the other hand, from the viewpoint of energy saving, it is not desirable to judge the battery life to be short. Since the fire alarm device 10 according to the first embodiment can accurately determine the battery life, it is possible to obtain a fire alarm device capable of reducing the waste of the battery while continuously executing the original function.

  In the first embodiment, the case where the first operation unit corresponds to the alarm sounding circuit 8 has been described as an example. However, other circuits constituting the fire alarm 10 may be used as the first operation unit, and similarly. The effect of can be obtained. Moreover, when applying this invention to the fire alarm of the structure which provides display parts, such as a liquid crystal screen, a liquid crystal display circuit can also be made into a 1st operation | movement part. In addition, a plurality of first operation units that are supplied with power from both the battery 2 and the internal power supply 12 may be provided.

Embodiment 2. FIG.
In the second embodiment, a fire alarm having a power system different from that of the first embodiment will be described. The basic functions such as fire alarm and periodic transmission of the fire alarm described in the second embodiment are the same as those in the first embodiment. In addition, the same or corresponding components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described.

FIG. 5 is a block diagram showing the main configuration of the fire alarm 10A according to the second embodiment.
In FIG. 5, the alarm sounding circuit 8 is connected only to the battery 2 and supplied with power, unlike the first embodiment, and is not supplied with power from the internal power supply 12.

  The pseudo resistance circuit 31 is a circuit configured with a resistor or the like for applying a pseudo load to the primary side of the internal power supply 12, and is connected to the battery 2 in parallel with the alarm sounding circuit 8. The pseudo resistance circuit 31 has a resistance value that corresponds to the maximum load of the transmission / reception circuit 5 and the alarm sounding circuit 8 that are directly supplied with power from the battery 2.

  The pseudo resistance circuit 32 is a circuit configured by a resistor or the like for applying a pseudo load on the secondary side of the internal power supply 12, and is connected to the internal power supply 12 in parallel with the fire detection circuit 7. . The pseudo resistance circuit 32 has a resistance value that corresponds to the maximum load of the control circuit 1, the fire detection circuit 7, and the indicator lamp circuit 9 to which power is supplied from the internal power supply 12.

  The pseudo resistance circuits 31 and 32 are in an OFF state and not electrically connected except when the battery voltage is detected.

  In the second embodiment, the second operation unit of the present invention is the alarm sounding circuit 8, the third operation unit is the fire detection circuit 7, the third pseudo load is the pseudo resistance circuit 31, and the fourth pseudo load. Corresponds to the pseudo resistance circuit 32, respectively.

In the fire alarm device 10A configured as described above, an operation for determining the battery life by determining the battery voltage of the battery 2 will be described. Here, it is assumed that the maximum electric load is applied to the fire alarm 10A when the alarm sounding circuit 8 sounds an alarm sound.
Note that the battery voltage determination operation of the fire alarm 10A according to the second embodiment is substantially the same as that of the first embodiment, and will be described with reference to FIG.

  When the battery voltage detection timing comes (S201), the control circuit 1 turns on the pseudo resistance circuits 31 and 32 (S202). The battery voltage detection circuit 4 A / D converts the detected battery voltage and outputs this value (referred to as a battery voltage value) to the control circuit 1 (S203). The battery voltage value detected here is the measurement of the battery voltage of the battery 2 when a load equivalent to the maximum load of the transmission / reception circuit 5, the alarm sounding circuit 8, the fire detection circuit 7, and the indicator lamp circuit 9 is applied. Value.

The control circuit 1 compares the acquired battery voltage value with a predetermined threshold value for the battery exhaust voltage (S204), and determines that the battery voltage value is normal if the battery voltage value is equal to or greater than the threshold value (S205). Normal means that the battery is not dead.
On the other hand, if the battery voltage value is less than the threshold value, it is determined that the battery has run out (S206). The voltage threshold is appropriately set in consideration of the value of the battery voltage necessary for the transmission / reception circuit 5 and the alarm sounding circuit 8 to operate at the maximum load.

  Thus, according to the fire alarm 10A according to the second embodiment, for each power system to each circuit constituting the fire alarm 10A, a pseudo resistance circuit having the same resistance value as the maximum load of each power system. 31 and 32 were arranged. For this reason, the battery voltage can be detected in a state in which a current consumed in each power supply system is generated in a pseudo manner at the maximum load of the fire alarm 10A. Therefore, the battery voltage can be determined more accurately. In addition, since the battery voltage can be accurately determined, the battery life can be determined more accurately.

Embodiment 3 FIG.
In the first and second embodiments, the example in which the battery voltage is determined based on the maximum load of the entire fire alarm has been described. In the third embodiment, an example of determining whether or not there is a remaining battery level that allows the circuit to operate not only at the maximum load of the entire fire alarm but also for each circuit connected to each power supply system will be described. To do. The basic functions such as fire alarm and periodic transmission of the fire alarm described in the third embodiment are the same as those in the first and second embodiments. In addition, the same or corresponding components as those in the first embodiment are denoted by the same reference numerals, and different points will be mainly described.

FIG. 6 is a block diagram showing the main configuration of the fire alarm 10B according to the third embodiment.
The transmission / reception circuit 5 and the alarm sounding circuit 8 are directly connected to the battery 2 and supplied with power.
The control circuit 1 and the fire detection circuit 7 are connected to an internal power supply 12 and supplied with power.
In addition, the fire alarm 10B includes an internal power supply 13. The internal power supply 13 is a constant voltage circuit that keeps the voltage supplied from the battery 2 constant. The indicator lamp circuit 9 is connected to the internal power supply 13 and supplied with power.
That is, the fire alarm device 10 </ b> B has three power supply systems: a power supply system from the battery 2, a power supply system from the internal power supply 12, and a power supply system from the internal power supply 13.

  The pseudo resistance circuit 41 is a circuit composed of a resistor or the like for applying a pseudo load on the primary side of the internal power supplies 12 and 13, and is connected to the battery 2 in parallel with the alarm sounding circuit 8. The pseudo resistance circuit 41 has a resistance value corresponding to the maximum load of the transmission / reception circuit 5 and the alarm sounding circuit 8 that are directly supplied with power from the battery 2.

  The pseudo resistance circuit 42 is a circuit configured by a resistor or the like for applying a pseudo load to the secondary side of the internal power supply 12, and is connected to the internal power supply 12 in parallel with the fire detection circuit 7. The pseudo resistance circuit 42 has a resistance value having a magnitude corresponding to the maximum load of the control circuit 1 and the fire detection circuit 7 supplied with power from the internal power supply 12.

  The pseudo resistance circuit 43 is a circuit configured by a resistor or the like for applying a pseudo load to the secondary side of the internal power supply 13, and is connected to the internal power supply 13 in parallel with the indicator lamp circuit 9. The pseudo resistance circuit 43 has a resistance value having a magnitude corresponding to the maximum load of the indicator lamp circuit 9 to which current is supplied from the internal power supply 13.

  The pseudo resistance circuits 41, 42, and 43 are in an OFF state and not electrically connected except when the battery voltage is detected.

  In the third embodiment, the second operation unit of the present invention is the alarm sounding circuit 8, the third operation unit is the fire detection circuit 7 or the indicator lamp circuit 9, and the third pseudo load is the pseudo resistance circuit 41. The fourth pseudo load corresponds to the pseudo resistance circuit 42 or the pseudo resistance circuit 43, respectively.

  In the fire alarm device 10B configured as described above, an operation for determining the battery life by determining the battery voltage of the battery 2 will be described. Here, when the alarm sounding circuit 8 sounds an alarm sound, the maximum electrical load is applied to the fire alarm 10B.

FIG. 7 is a flowchart showing a battery voltage determination operation according to the third embodiment.
In FIG. 7, when the battery voltage detection timing comes (S301), a circuit (operation unit) to be determined is selected (S302). In the subsequent flow, it is determined whether or not there is a sufficient remaining battery capacity for driving the selected circuit.

When determining the circuit directly connected to the battery 2, only the pseudo resistance circuit 41 is turned on (S303). Then, the battery voltage detection circuit 4 performs A / D conversion on the detected battery voltage and outputs the battery voltage value to the control circuit 1 (S304). The battery voltage value detected here is a measured value of the battery voltage of the battery 2 when a load equivalent to the maximum load of the transmission / reception circuit 5 and the alarm sounding circuit 8 is applied.
The control circuit 1 compares the acquired battery voltage value with a predetermined voltage threshold A (S305), and determines that the battery voltage value is normal if the battery voltage value is equal to or greater than the voltage threshold A (S306). In other words, the normal state means that the transmission / reception circuit 5 and the alarm sounding circuit 8 directly connected to the battery 2 have sufficient battery power to operate normally in the maximum load state. On the other hand, if the battery voltage value is less than the threshold value A, it is determined that the operation of the circuit directly connected to the battery 2 is unstable (S307). The voltage threshold A is appropriately set in consideration of the value of the battery voltage necessary for the transmission / reception circuit 5 and the alarm sounding circuit 8 to operate at the maximum load.

Further, when determining the circuit connected to the internal power supply 12, the pseudo resistance circuit 42 is turned on (S308). Then, the battery voltage detection circuit 4 performs A / D conversion on the detected battery voltage, and outputs the battery voltage value to the control circuit 1 (S309). The battery voltage value detected here is the value of the battery voltage of the battery 2 when a load equivalent to the maximum load of the control circuit 1 and the fire detection circuit 7 is applied.
The control circuit 1 compares the acquired battery voltage value with a predetermined voltage threshold B (S310), and determines that the battery voltage value is normal if the battery voltage value is equal to or greater than the voltage threshold B (S311). That is, it means that the control circuit 1 and the fire detection circuit 7 connected to the internal power supply 12 have sufficient battery power to operate normally in the maximum load state. On the other hand, if the battery voltage value is less than the threshold value B, it is determined that the operation of the circuit connected to the internal power supply 12 is unstable (S312). The voltage threshold B is appropriately set in consideration of the value of the battery voltage necessary for the control circuit 1 and the fire detection circuit 7 to operate at the maximum load.

Further, when determining the circuit connected to the internal power supply 13, the pseudo resistance circuit 43 is turned on (S313). Then, the battery voltage detection circuit 4 A / D converts the detected battery voltage and outputs the battery voltage value to the control circuit 1 (S314). The battery voltage value detected here is the value of the battery voltage of the battery 2 when a load equivalent to the maximum load of the indicator lamp circuit 9 is applied.
The control circuit 1 compares the acquired battery voltage value with a predetermined voltage threshold C (S315), and determines that the battery voltage value is normal if the battery voltage value is equal to or greater than the voltage threshold C (S316). That is, it means that the indicator light circuit 9 connected to the internal power supply 13 has a battery level sufficient for normal operation under the maximum load condition. On the other hand, if the battery voltage value is less than the threshold value C, it is determined that the operation of the circuit connected to the internal power supply 13 is unstable (S317). The voltage threshold C is appropriately set in consideration of the value of the battery voltage necessary for the indicator lamp circuit 9 to operate at the maximum load.

If all the circuits are determined, the pseudo resistance circuits 41, 42, 43 are turned on (S318). Then, the battery voltage detection circuit 4 performs A / D conversion on the detected battery voltage, and outputs the battery voltage value to the control circuit 1 (S319). The battery voltage value detected here is that of the battery 2 when a load equivalent to the maximum load of the transmission / reception circuit 5, the alarm sounding circuit 8, the control circuit 1, the fire detection circuit 7, and the indicator lamp circuit 9 is applied. This is the value of the battery voltage.
The control circuit 1 compares the acquired battery voltage value with a predetermined voltage threshold value All (S320), and determines that the battery voltage value is normal if the battery voltage value is equal to or greater than the voltage threshold value All (S321). That is, the transmission / reception circuit 5 and the alarm sounding circuit 8 directly connected to the battery 2, the control circuit 1 and the fire detection circuit 7 connected to the internal power supply 12, and the display connected to the internal power supply 13 This indicates that the battery circuit 9 has enough battery power to operate normally at the maximum load. On the other hand, if the battery voltage value is less than the threshold value All, it is determined that the fire alarm 10B is out of battery (S322). The voltage threshold value All is appropriately set in consideration of the value of the battery voltage necessary for all circuits constituting the fire alarm device 10B to operate at the maximum load.

  In this way, it can be determined whether the operation of each circuit can become unstable or whether the battery runs out. If it is determined that the remaining battery voltage is not normal, for example, the alarm sounding circuit 8 or the indicator lamp circuit 9 is operated to notify the user. Alternatively, a signal indicating that the battery voltage is insufficient may be transmitted by the transmission / reception circuit 5 to another fire alarm or a monitoring device.

  Thus, according to the fire alarm device 10B according to the third embodiment, the pseudo resistance circuit having the same resistance value as the maximum load of each power supply system for each power supply system to each circuit constituting the fire alarm device 10B. 41, 42 and 43 were arranged. For this reason, the battery voltage can be detected in a state in which a current consumed by each power supply system is generated in a pseudo manner at the maximum load of the fire alarm 10B. Therefore, the battery voltage can be determined more accurately. In addition, since the battery voltage can be accurately determined, the battery life can be determined more accurately.

  Further, the battery voltage is detected in a state where only one of the pseudo resistance circuits is turned on, and the battery voltage is determined by comparing with a predetermined threshold value. For this reason, it is possible to determine whether the remaining battery level is insufficient for each circuit connected to each power supply system. For this reason, it is possible to determine the battery life according to the amount of load, such as whether there is a remaining battery level at which “alarm sound can be sounded” or a remaining battery level at “only capable of fire detection”. . Therefore, a more detailed alarm can be given regarding the remaining battery level, and the fire alarm device 10B can continue to operate appropriately.

  In the third embodiment, the case where two internal power supplies are provided has been described as an example. However, the number of internal power supplies is not limited to this, and if there are many circuits constituting a fire alarm, separate internal power supplies are required. It is good also as a structure to provide, and the same effect can be acquired. In the third embodiment, an example of driving a load connected to any one of the internal power supplies or all loads has been described. However, the number of loads to be driven is changed according to an assumed use state. May be.

  In the above description, the case where the present invention is applied to a fire alarm device that performs wireless communication has been described as an example. However, the communication method is not limited to wireless communication, and an alarm device for detecting an abnormality in addition to the fire alarm device. It is also possible to apply to. Moreover, you may use for the receiver, detector, etc. of an automatic fire alarm system.

  DESCRIPTION OF SYMBOLS 1 Control circuit, 2 Battery, 4 Battery voltage detection circuit, 5 Transmission / reception circuit, 6 Antenna, 7 Fire detection circuit, 8 Alarm sounding circuit, 9 Indicator light circuit 10, 10A, 10B Fire alarm device, 11 Memory element, 12 , 13 Internal power supply, 21, 22, 31, 32, 41, 42, 43 Pseudo resistance circuit, 100 Alarm system.

Claims (4)

Battery,
A constant voltage circuit for keeping the voltage supplied from the battery constant;
A state detector;
A state determination unit that determines a state based on an output signal of the state detection unit;
A control unit that outputs a warning based on the determination result of the state determination unit, and an alarm device comprising:
A battery voltage detection unit for detecting a voltage supplied from the battery to the control unit;
A first operating unit connected to the battery and the constant voltage circuit and powered from both ;
Wherein connected in parallel with the first operation unit to the battery, when usually a OFF state, the first dummy load you corresponds to the maximum load of a circuit including the first operation unit power directly supplied from the battery When,
It is connected before and parallel to the first operation portion Kijo voltage circuit, when usually a is OFF, you corresponds to the maximum load of a circuit including the first operation portion to which the power supply from the constant voltage circuit supplied have a second dummy load,
The said control part measures the voltage value of the said battery voltage detection part in the state which connected the said 1st pseudo load and the said 2nd pseudo load, The alarm device characterized by the above-mentioned. The alarm device according to claim 1, wherein the first operation unit is an alarm sounding circuit. Battery,
A constant voltage circuit for keeping the voltage supplied from the battery constant;
A state detector;
A state determination unit that determines a state based on an output signal of the state detection unit;
A control unit that outputs a warning based on the determination result of the state determination unit, and an alarm device comprising:
A battery voltage detection unit for detecting a voltage supplied from the battery to the control unit;
Connected to the battery, and a second operation unit that will be powered from the battery,
Connected to said constant-voltage circuit, and a third operation unit that the Ru is power supplied from the constant voltage circuit,
Wherein connected in parallel with said second operation unit to the battery, when usually a OFF state, the third dummy load you corresponds to the maximum load of a circuit including the second operation unit power directly supplied from the battery When,
Is pre-connected in parallel with the third operation portion Kijo voltage circuit, when normally an OFF state, it corresponds to the maximum load of a circuit including the third operation portion to which the power supply from the constant voltage circuit supplied have a fourth pseudo load,
The controller is configured to electrically connect the third pseudo load and the fourth pseudo load, to electrically connect the third pseudo load, and to electrically connect the fourth pseudo load. An alarm device characterized in that, in each of the states, the battery life is determined by measuring a voltage value of the battery voltage detector . The second operation unit is an alarm sounding circuit,
The alarm device according to claim 3, wherein the third operation unit is a fire detection circuit or an indicator lamp circuit.

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